An electrostatic rotary sprayer for coating product including a spraying cup, a body and a drive turbine assembled in the body and configured to rotate the spraying cup about an axis of rotation defined by the body. The sprayer also includes electrodes for charging the coating product sprayed by the spraying cup, these electrodes being assembled on a ring attached on the body, and a skirt for discharging air around the cup. An annular slit, supplied by a pressurized air flow circuit with pressurized air, is defined radially between the ring and the skirt, with its outlet oriented toward the front of the sprayer.

Disclosed are a coating apparatus and a coating method. The coating apparatus includes a chamber, a support located in an interior space of the chamber and configured to support a substrate which is to be coated, an ejection nozzle configured to eject a coating material toward the support, and an electric field forming unit configured to form an electric field in a movement path of the coating material to provide kinetic energy for the coating material.

A method and apparatus for fabricating multifunction membranes comprising cross-aligned nanofiber in an electrospinning device, the method comprising providing a multiple segment collector including at least a first segment, a second segment, and an intermediate segment to collectively present an elongated cylindrical structure; electrically charging an edge conductor circumferentially resident on the first segment and on the second segment; rotating the elongated cylindrical structure on a drive unit around a longitudinal axis; the elongated cylindrical structure holding electrospun fiber substantially aligned with the longitudinal axis when the edge conductors are excited with a charge of opposite polarity relative to charged fiber, and attracting electrospun fiber on to its surface around the longitudinal axis at least when the edge conductors are absent a charge or grounded and a charged electrode is positioned opposite a fiber emitter; and repeating the process multiple times to form layers of nanofibers encapsulating agents of interest.

This method allows a coating product to be applied to a component (13) being moved by a conveyor (12), along which conveyor at least one spray (62.1, 62.2) is arranged. It comprises automated steps involving determining, within a fixed frame of reference (X12, Y12, Z12), the coordinates of the points (A1, B1, C1, A2, B2, C2) of one or more lines (L1, L2) of the exterior profile of the component which are distributed along the length of the component, in assigning to each spray the points of each exterior profile line that lie within its field of spraying, in identifying, from among the points assigned to each spray, the point (A1, A2; B1, B2) closest to the spray for each exterior profile line, in determining, for each spray, a line (L3, L4) to follow that passes through all the points (A1, A2, B1, B2) closest to the spray as identified in step c), and in establishing a reference path for each spray according to the points on the line (L3, L4) to follow so that the application distance of each spray is adjusted automatically and independently according to the exterior profile of the component.

Transfer rings for use in coating substrates and methods of utilizing same are disclosed. The transfer rings disclosed herein are useful in efficiently moving a plurality of substrates between different process chambers. For instance, the transfer rings are designed to collectively move a plurality of stents between coating and sintering chambers.

A cross bar for powder coating and electronic coating, and methods for forming the same. A connector extends between a front portion and a rear portion. Embosses are located in the front and rear portions to connect with each other. Drain holes are provided at spaced intervals along the front and rear portions, offset from one another.

Embodiments relate to a system for manufacturing nano-scale energy harvesters and electric power generators. The system includes a plurality of dispensers to dispense a first material, a second material, and a separation material between the first and second materials. The first material has a first work function value and the second material has a second work function value different from the first work function value. At least one electrospray device is positioned proximal to the third dispenser to deposit a fluid within at least a portion of the separation material. The fluid has particles with a third work function value different from the first and second work function values. The system also includes a guide assembly to transport the first and second electrodes, the positioned separation material, and the fluid to a joint proximal position and form a fabricated product.

An apparatus for accumulating cross-aligned fiber in an electrospinning device, comprising a multiple segment collector including at least a first segment, a second segment, and an intermediate segment, the intermediate segment positioned between the first and second segment to collectively present an elongated cylindrical structure; at least one electrically chargeable edge conductor circumferentially resident on the first segment and circumferentially resident on the second segment; a connection point on the first segment and on the second segment, the connection points usable for mounting the elongated cylindrical structure on a drive unit to rotate around a longitudinal axis; the elongated cylindrical structure holding electrospun fiber substantially aligned with the longitudinal axis when the edge conductors are excited with a charge of opposite polarity relative to charged fiber, and attracting electrospun fiber on to its surface around the longitudinal axis at least when the edge conductors are absent a charge or grounded.

A method and apparatus for fabricating multifunction membranes comprising cross-aligned nanofiber in an electrospinning device, the method comprising providing a multiple segment collector including at least a first segment, a second segment, and an intermediate segment to collectively present an elongated cylindrical structure; electrically charging an edge conductor circumferentially resident on the first segment and on the second segment; rotating the elongated cylindrical structure on a drive unit around a longitudinal axis; the elongated cylindrical structure holding electrospun fiber substantially aligned with the longitudinal axis when the edge conductors are excited with a charge of opposite polarity relative to charged fiber, and attracting electrospun fiber on to its surface around the longitudinal axis at least when the edge conductors are absent a charge or grounded and a charged electrode is positioned opposite a fiber emitter; and repeating the process multiple times to form layers of nanofibers encapsulating agents of interest.

An apparatus for accumulating cross-aligned fiber in an electrospinning device, comprising a multiple segment collector including at least a first segment, a second segment, and an intermediate segment, the intermediate segment positioned between the first and second segment to collectively present an elongated cylindrical structure; at least one electrically chargeable edge conductor circumferentially resident on the first segment and circumferentially resident on the second segment; a connection point on the first segment and on the second segment, the connection points usable for mounting the elongated cylindrical structure on a drive unit to rotate around a longitudinal axis; the elongated cylindrical structure holding electrospun fiber substantially aligned with the longitudinal axis when the edge conductors are excited with a charge of opposite polarity relative to charged fiber, and attracting electrospun fiber on to its surface around the longitudinal axis at least when the edge conductors are absent a charge or grounded.